David Buckley, SALT 1
Background is really just monochromatic photometry History 1637 Descartes explained the origin of the rainbow. 1666 Newton s classic experiments on the nature of colour. 1752 Melvil discovered the yellow D lines emitted by sodium vapour. 1802 Wollaston discovered dark lines in the spectrum of the Sun. 1814 Fraunhofer used a small theodolite telescope to examine stellar spectra and found similar lines as in the solar spectrum. He catalogued the features as A, B, C,... etc, some which persist to the present day the sodium D lines, the G band (CN - cyanogen). 2
Background 1859 Kirchhoff & Bunsen experiments established that a heated surface emits a continuous (Planck or black body ) spectrum a heated low pressure gas emits an emission spectrum with discrete lines at wavelengths characteristic of the gas; and a cool low pressure» Examples include planetary nebula & HII (ionized hydrogen) region gas in front of a hot source absorbs at those same characteristic wavelengths.» Examples include the photospheres of stars (black bodies with absorbing atmospheres 3
First achieved with glass prisms Highly transparent Optical/IR Observational Astronomy How to disperse light? Made from material with higher index of refraction than air Bends the lights Made from material with wavelength dependent index of refraction Disperses light Degree of bending is wavelength dependent Index of refraction, n, is ratio of speed of light in vacuum compared to speed of light in the material 4
Index of Refraction Non-linear with wavelength Degree of dispersion also non-linear Original spectrographs used prisms Continued well into 20 th C But, problems with prisms. They cannot achieve very high dispersion, therefore can t do high resolution (R = λ/ λ) spectroscopy They re quite lossy :» reflection losses at air-glass surfaces (4% per surface for uncoated prisms)» Absorption losses in the glass, particularly in the UV Temperature changes can cause index changes Dispersion changes and line shifts 5
Just apply Snell s law n 1 sin i = n 2 sin r From air-to-glass (n 1 = 1, n 2 = 1.5) n 2 = sin i / sin r Geometry for generalized case Optical/IR Observational Astronomy Dispersion Formula for Prisms Deviation is: δ = i + r - α Dispersion is simply: θ/ λ λ = dδ/dλ 6
More on Prisms Prisms Used in minimum deviation condition Symmetrical» Beam width constant No astigmatism From trig: So dispersion depends on» Apex angle of prism» Emergent angle of diffraction» Index of refraction dependency on λ Spectral resolution is given as: R = λ / λ = B dn/dλ (slitless) (higher resolution in blue compared to red) θ 7
This is basis of all prism spectrographs Optical/IR Observational Astronomy Prism Spectrographs First used as objective prisms Prisms placed at telescope aperture 8
Used to disperse images on the sky Create multiple low resolution spectra Resolution determined by the prism dispersion, detector resolution and seeing First done with photographic plates e.g. on the Cape Observatory McLean refractor Optical/IR Observational Astronomy Objective Prism Surveys Image Spectrogram (dispersed image) 9
Objective Prisms Spectra widened by trailing telescope in direction perpendicular to dispersion Easier to see features by eye (first techniques) First catalogue of stellar spectra done at Harvard College Observatory by Annie Cannon Laboriously catalogued 250,000 stars, by eye! 10
Objective Prisms Surveys Combined with Schmidt telescope, objective prisms could be used to spectroscopically survey large areas of sky Multiplex advantage: area coverage and wavelength information 11
Search for emission line objects e.g. star formation in galaxies Optical/IR Observational Astronomy Example of Objective Prisms Spectra 12
Spectral classification Optical/IR Observational Astronomy Example of Objective Prisms Spectra 13
Problems with Objective Prisms Low spectral resolution Spectra are smeared Overlapping objects in a dense field Non- linear dispersion Generally only for relatively bright objects 14
Uses the wave properties of light Interference fringes Optical/IR Observational Astronomy Diffraction Gratings Interference from periodic structures Equally spaced grooves Either in reflection or transmission 15
Diffraction Gratings For constructive interference: For multiple slits, fringes become narrower 16
Diffraction Gratings: Grating Equation Constructive interference occurs when the path difference between two diffracted waves differs by an integral number of wavelength Dispersion given as Proportional to order, m Inversely proportional to spacing, d (proportional to line density, l = 1/d) e.g. 300 l/mm grating is lower resolution than 1200 l/mm 17
Diffraction Gratings: Free Spectral Range For a given diffraction angle different orders can overlap, satisfying the condition: So a first order (m = 1) diffracted wavelength at 800 nm overlaps with the second order (m=2) diffracted wavelength at 400 nm and third order (m=3) diffracted wavelength at 266.7 nm Typically we use order separating filters if detectors are sensitive to these higher order diffracted wavelengths Free Spectral Range is that part of a spectrum free of overlapping orders More of an issues for gratings designed to work at high orders (e.g. echelle gratings) 18
Grating Blaze The tilt angle of the grating facets with respect to grating surface normal Most efficient angle, since diffraction at the blaze angle obeys reflection condition of i = r Diffraction efficiency drops off moving away from the blaze angle/wavelength 19
Grating Efficiencies Grating efficiency drops off moving away from blaze wavelength: 20
Echelle Gratings High resolution gratings avhieved by making the blaze condition (highest efficiency) satisfied and high orders (e.g. m = 50 100) High orders overlap, so need to separate them Cross dispersion with another low resolution grating or prism 21
Echelle Gratings: Cross Dispersion GIRAFFE spectrograph (1.9-m SAAO) 22
High resolution echellograms Optical/IR Observational Astronomy Echelle Gratings 23
Uses properties of both gratings and prisms Optical/IR Observational Astronomy Grisms Useful for high efficiency & low resolution Can keep the diffracted rays straight through (no deviation angle) 24
Gratings Optical/IR Observational Astronomy Grisms All things comes from the basic grating equation: Grisms (combined grating+prism) Blaze angle (facet angle to normal) = incidence angle (on grating) Normal incidence on prism face Blaze angle = angle of refraction of prism Resolution given as: 25
Review of Reflection Gratings Transmission Grating Reflection Grating sin θ = m n λ n = groove density (grooves or lines / mm) m = spectral order number (m = 1, 2, 3 ) α = angle of incidence (independent of λ) Β = angle of diffraction (λ dependent) sin α + sin β = m n λ 26
Reflection Gratings Mirror 27
m = +1 m = -1 Reflection grating (n=small, low dispersion) 28
m = -1 m = +1 Reflecting grating (n=large, high dispersion) 29
Free Spectral Range (FSR) 30
m = -1 m = +1 Blazed reflection grating (blazed at +1 order red) 31
m = -1 m = +1 Blazed reflecting grating (blazed at -1 order red) 32
New Grating Technology: Volume Phase Holographic Gratings Uses properties of Bragg diffraction in crystals 33
Volume Phase Holographic Gratings Uses a volume (depth) of material Photosensitive material (dichromated gelatin) has laser hologram exposed in it Processing produces modulation of refractive index Diffraction occurs in transmission through material Dichromated gelatin layer (exposed to laser hologram) Incident ray diffracted ray Work at the Bragg condition: α = β Optically flat fused silica or BK7 glass (can AR coat) Thickness (d) is > than depth of groove in surface-relief grating. Implies efficiency profile governed by Bragg diffraction. 34
Wavelength of operation is tuneable Efficiencies can be very high Now used in most modern astronomical spectrographs Optical/IR Observational Astronomy Volume Phase Holographic Gratings 35
Recap on Dispersers Volume Phase Holographic gratings (VPHGs) Diffraction at the Bragg condition (α = β) Grating equation for a VPHG is: Where Λ= index plane ( groove ) density, α 2b = Bragg angle w.r.t. index planes, n2 = index of refraction of DCG layer Used extensively on the SALT RSS 36
Real Instruments Imaging camera (like SALTICAM, but not quite) SALTICAM does not collimate (beam at f/2)» Not so important for broad band filters RSS imaging mode does collimate» Much more important for narrow band interference filters Spectrometer 37
Generic Grating Spectrograph x w Imaging camera (like SALTICAM, but not quite) i θ 38
SAAO 1.9-m Cassegrain Spectrograph 39
RSS: Robert Stobie Spectrograph PFIS re-named in memory of Bob Stobie, previous SAAO Director and one of the instigators of SALT and first Chairman of SALT Board. 40
RSS VPHG tuning : Articulate (rotate grating & camera) to change wavelength & resolution 41
Example of an RSS VPHG Note the dark shadow: implies little zero order throughput. Most of the light is diffracted into the first order 1300 gr/ mm VPH 42
Effect of bad focus and seeing in Slit width/ Slit loss 43
The Spectrograph Slit 44
Signal to Noise 45
Signal to Noise in mags S/N δmag 2 0.44 10 0.10 100 0.01 46
Signal to Noise S/N Calculations So, what do you do with this? Demonstrate feasibility Justify observing time requests Get your observations right Estimate limiting magnitudes Discover problems with instruments, telescopes or observations So, how do you calculate it? Could use the S/N formula need to know which regime you re operating in need to know the various parameter (pixel scale, gain, RN, Dark count, etc.) Usually there are simple tools available to calculate all of this for you! 47
Sky Background 48
Two most common cases 49
Effect of bad focus and seeing in Signal-to-Noise for typical SALT case Good seeing Bright object: not so affected S N O O ~ Bad seeing: n times bigger seeing psf S N O O Faint object [Background (sky) dominating]: badly affected S N O B > S O O 1 = N 2 Bn B n 50
Calibration frames: * Bias frame (electronic DC level) - sometimes derived from overscan or prescan * Flat field (detector sensitivity) * Arc Lamp (wavelength calibration) * Flux Standard - flux from electrons cm -2 sec -1 Å -1 to ergs/cm -2 sec -1 Å -1 * Fringe frame correction Optical/IR Observational Astronomy Reducing Spectroscopic Data bias flat field arc line spectrum Basic reduction procedures: 1. Bias correction 2. Flat fielding 3. Cosmic ray removal 4. Wavelength determination 5. Background subtraction 6. Spectrum extraction 7. Flux calibration (remove atm. effects) 2D object spectrum fringe frame 51
Wavelength Calibrations Determine wavelength as a function of pixel number on the detector Typically use 3 rd order polynomial fit to known wavelengths Need to have order blocking filters to exclude 2 nd order overlap in the 1 st order, 3 rd in 2 nd, etc. 52
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